Design Planning: Collaborate on sketches or outlines for hardware components, ensuring alignment with your vision.

Materials and Tools: Provide advice on selecting cost-effective, sustainable materials and equipment.

Prototyping Concepts: Help draft blueprints or step-by-step instructions for creating prototypes.

Integration Strategies: Discuss how to incorporate hardware into your broader scientific framework.

Project Management: Suggest ways to streamline workflow, manage resources, and track progress.

Medical professionals performing surgery with advanced technology, including a patient on an operating table surrounded by various screens and equipment.

Crystal junction and resonance research, you might focus on these key areas:

  1. Piezoelectric Properties: Investigate how mechanical stress or vibrations influence electrical energy generation in crystal junctions.

  2. Resonance and Frequency Response: Use your oscilloscopes and AWG generators to study how crystals behave under different frequencies and amplitudes—particularly in relation to energy harmonics.

  3. Dielectric and Impedance Analysis: Employ your vector network analyzer to measure impedance and signal transmission, offering clues about how energy flows through these junctions.

  4. Physical Modification: Your diamond drills are ideal for fine adjustments to crystal structure, enabling controlled experiments on how geometry impacts energy behavior.

  5. Quantum Field Interactions: Explore whether these junctions reveal interactions with subtle energy fields, such as those tied to your project’s focus on biofields and chakra energies.

  6. Test platform 3.0, described and constructed as current revision with documented modifications. ie: frequency sweeps, amplitude, field intensity at center of Coil 3.0.

  7. Other integrated devices as documented for harmonic, subharmonic and side bands.

🔧 OpenMedBed Scalar Research Platform – Hardware Inventory

Last Updated: May 25, 2025

1. Arbitrary Waveform Generators (AWGs)

  • JDS6600-FU
    Dual outputs, 60 MHz max frequency, AM/FM/sweep/burst, phase control
  • FeelTech FY2300-20
    20 MHz dual-channel DDS, waveform editing, used for subharmonics
  • FY8300S-20
    20 MHz three independent channel, USB upload, excellent for AM/ELF injection

2. Oscilloscope

  • Siglent SDS1104X-E
    4-channel, 100 MHz bandwidth, 1 GSa/s, advanced FFT + XY mode

3. Vector Network Analyzer (VNA)

  • NanoVNA-H v3.6
    10 kHz – 1.5 GHz, S11/S21, Smith charts, USB interface

4. Spectrum Analyzer

  • URSINC TinySA Ultra+ ZS406 (2025 HW V0.4.6)
    100 kHz – 5.4 GHz, dual-mode, great for scalar influence mapping

Here are a few ideas to enhance your construction process:

  1. Geometric Accuracy: Use your lathes and mills to experiment with intricate crystal shapes—potentially exploring how facets or specific curvatures influence energy transmission or resonance.

  2. Surface Optimization: Your special lapping compound might allow you to achieve exceptionally smooth interfaces, which could be vital for ensuring efficient energy flow across junctions. Testing its effectiveness with various crystal types might uncover new properties.

  3. Hybrid Junctions: Combine different crystal materials to create composite junctions, potentially unlocking synergies between their respective energetic or piezoelectric properties.

  4. Controlled Experiments: Correlate physical modifications to measurable outcomes using your oscilloscopes and vector network analyzers—for instance, observing how structural changes impact impedance or signal fidelity. Documentation is important for comparison.

  5. Patience: the winding of coils is tedious and requires precision. Expect to spend up to 40 hours in building this configuration (3.0).